Water-stress-induced inhibition of α-tubulin gene expression during growth, and its implications for reproductive success in rice.

A drought-suppressed cDNA (RiP-3), encoding a putative α-tubulin protein was isolated from rice panicle at pollen-mother-cell meiosis stage. Analysis of its deduced amino acid sequence showed all the typical structural motifs for plant α-tubulins. The expression of α-tubulin transcripts was observed in all the reproductive organs of rice panicle, and in 5- or 15-day old seedlings, but not in mature leaves. Expression levels were positively correlated with the regions and periods of high growth, and the transcript level declined in parallel with drought-induced reduction in growth rates in all tissues examined. Immunoblot analysis of proteins separated by SDS-PAGE with anti-α-tubulin monoclonal antibody showed that the level of protein paralleled the changes in the transcript abundance in these organs. In situ immunolocalization of the α-tubulin protein in sections of the basal part of 5-day old seedlings showed that the highest levels of the protein were associated with the fastest growing leaf whorls, and the protein level declined upon a brief episode of water stress. Given the known critical role of tubulin in cell division and elongation, the results indicate that the expression of α-tubulin gene may be part of the events that suppress panicle elongation during water deficit, which is in turn a suspected cause of male reproductive failure and yield reduction in rice.

Cloning and functional expression of two plant thiol methyltransferases: a new class of enzymes involved in the biosynthesis of sulfur volatiles.

Glucosinolates are defensive compounds found in several plant families. We recently described five distinct isoforms of a novel plant enzyme, thiol methyltransferase (TMT), which methylate the hydrolysis products of glucosinolates to volatile sulfur compounds that have putative anti-insect and anti-pathogen roles. In the work presented here, two cDNAs encoding these enzymes (cTMT1 and cTMT2) were isolated by screening a cabbage cDNA library with an Arabidopsis EST showing high sequence homology to one TMT isoform. The genomic clone of cTMT1 was subsequently amplified by PCR. Both cDNAs encoded polypeptides of identical lengths (227 amino acids) and similar predicted masses (ca. 25 kDa), but differing in 13 residues. The cDNAs contained the typical methyltransferase signatures, but were otherwise distinct from conventionally known N-, O- or S-methyltransferases. A chloride methyl transferase was the only gene with an assigned function that shared significant similarity with the TMT cDNAs. Southern analysis indicated single copy for each TMT gene. The two cDNAs were expressed in Escherichia coli. The substrate range, kinetic properties and molecular sizes of the purified recombinant proteins were comparable to those of the native enzyme. These data, together with the detection of the sequenced amino acid motif of one native TMT peptide in the cDNAs, confirmed that the latter were authentic TMTs. The expression pattern of the TMTs in various cabbage tissues was consistent with their association with glucosinolates. The cloning of this new class of plant genes furnishes crucial molecular tools to understand the role of this metabolic sector in plant defenses against biotic stress.